This heating cartridge includes a thermally conductive tube (42) to be immersed in a thermo-expandable substance of the thermostatic element, electric heating means (6) arranged inside the tube, and a base (7) made of a plastic substance, integral with a terminal longitudinal portion (44) of the tube and adapted to support the electric connection between the heating means and an external current source. In order to make the connection between the base and the tube both resistant and precisely adaptable to various heating cartridge geometries, and to do so economically, the terminal portion of the tube comprises an outwardly flared free end (45), which extends protruding both radially and axially from the rest of the terminal portion and in which the base is attached by overmolding.
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1. A heating cartridge for a thermostatic element, comprising:
a thermally conductive tube, having a longitudinal central axis and adapted to be immersed in a thermo-expandable substance of the thermostatic element,
electric heating means arranged inside the tube, and
a base made of a plastic substance, integral with an upper terminal portion of the tube and adapted to support the electric connection between the electric heating means and an external current source,
wherein the upper terminal portion of the tube includes an outwardly flared free end, which extends protruding both radially and axially from another portion of the upper terminal portion and in which the base is attached by overmolding.
9. A method for manufacturing a heating cartridge for a thermostatic element which has a thermally conductive tube having a longitudinal central axis, and which tube is adapted to be immersed in a thermo-expandable substance of the thermostatic element and in which electric heating means are arranged, the method comprising the steps of:
forming a free end of an upper terminal portion of the tube to flare the free end outward so that the free end extends protruding both radially and axially from another portion of the terminal portion, thereafter connecting a base made of a plastic substance to the upper terminal portion by overmolding the flared free end, and thereafter preparing the base to support an electric connection between the heating means and an external current source.
2. The cartridge according to
3. The cartridge according to
5. The heating cartridge according to
6. The heating cartridge according to
7. The heating cartridge according to
8. A thermostatic valve, comprising:
a heating cartridge according to
a case, in which a fluid circulates and which inwardly defines a blind cavity in which the base of the heating cartridge is housed and bears axially,
a plug for regulating the flow of fluid through the case, and
the thermostatic element including a fixed portion, fixedly connected to the case, and a mobile portion, which supports the plug and which can be moved in relation to the fixed portion under the action of expansion of a thermo-expandable substance in which the tube of the heating cartridge is immersed.
10. The method according to
11. The method according to
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1. Field of the Invention
The present invention relates to a heating cartridge for a thermostatic element, as well as a method for manufacturing such a cartridge. It also relates to a thermostatic valve including such a cartridge.
2. Brief Description of the Related Art
In many applications of the fluidics field, in particular for cooling of thermal engines of vehicles, thermostatic valves are used to distribute a fluid entering into different circulation channels, depending on the temperature of that fluid. These valves are called thermostatic in the sense that the movement of their internal plug(s) is controlled by a thermostatic element, i.e. an element which comprises a cup containing a thermo-expandable substance and a piston which is slidingly displaceable with respect to the cup under the action of the thermo-expandable substance during the expansion thereof.
In order to distribute the fluid depending on other parameters, in particular conditions outside the valve such as the ambient temperature or the load of the vehicle propelled by the engine equipped with the valve, it is known to integrate an electric cartridge into the valve to heat the thermo-expandable substance, which makes it possible to steer the valve from the outside thereof, independently or as a complement to the temperature of the entering fluid, in particular using a computer onboard the vehicle and programmed appropriately. In practice, the heating cartridge comprises electric heating means, such as a heating resistor, arranged inside the aforementioned piston or a similar tube: by immobilizing, for example, the piston at the external case of the valve, the electrical supply of the resistor causes an increase in temperature of the thermo-expandable substance, which causes, through expansion of the latter part, the sliding of the cup around the piston, a plug being supported by said cup to act on the circulation of the fluid through the valve.
In order to electrically supply the heating means, the cartridge comprises connectors to electrically connect electric conduction wires, belonging to the heating means, and charge ports connected to an external current source. These connectors are supported by a base integral with the tube, this base thus undergoing, at least in part, the strains absorbed by the piston during use.
In this context, DE-A-103 03 133 proposed to strengthen the mechanical resistance of the connection between the base and the tube, by realizing the base through molding of a plastic substance injected on either side of a flat clamping plate, provided at the end of the tube in a radial plane at said tube end. This radical solution has proven difficult to carry out in practice, inasmuch as it requires having injection molds adapted, simultaneously, to each possible shape and size for the tube and the total axial dimension that one wishes to obtain for the heating cartridge. The molding cost to meet the different geometries of heating cartridges therefore becomes crippling.
The aim of the present invention is to propose a heating cartridge whereof the connection between its tube and its base is both resistant and precisely adaptable to various geometries of heating cartridges, all while being economical to carry out.
To that end, the object of the invention is a heating cartridge for a thermostatic element, including:
The basic idea of the invention is not to try to realize the base by coating the entire terminal portion of the tube with plastic, which makes the base massive and not very precise, but to overmold the inside of the free end of the tube, flared specifically. To do this, said flared end presents an overmold face, turned opposite the rest of the tube, including components which are both radial and axial in relation to the axis of the tube: the radial component of the overmold interface between the tube and the base allows good transmission of axial strains, which avoids, during use, the tube damaging the base, in particular by shearing it, while the axial component of this interface makes it possible, on one hand, to improve the transverse positioning of the base, in particular by facilitating the placement of injection molds of the plastic substance of the base, and, on the other hand, to absorb transverse strains.
It is then advantageously possible to overmold the base by only making it extend axially from a single axial side of the terminal portion of the tube including the flared end. The flared end of the tube can thus serve as a reliable and precise reference to impose the axial dimension of the base during its molding, with a corresponding injection mold adjustment. In other words, it is the molding tool which gives the heating cartridge its effective functional length, by precisely controlling the measurement between the end of the heating cartridge and the axial face opposite the base, which avoids providing attached adjustment means, such as adjustment systems through screws, added wedges, etc.
Advantageously, a heating cartridge according to the invention also includes a gasket, preferably only one, which simultaneously surrounds the flared free end of the tube and is inserted between this flared free end and the base. This gasket which, in particular, is a shape gasket, makes it possible to simultaneously seal the inside of the tube and the electric connection supported by the base. Moreover, the closing of the injection mold of the base can be done on the gasket, which makes it possible to accommodate the dispersions of the total axial length of the heating cartridge.
According to other advantageous features of the heating cartridge according to the invention, taken alone or according to all technically possible combinations:
Another object of the invention is a thermostatic valve, including:
Another object of the invention is a method for manufacturing a heating cartridge for a thermostatic element, in which one has a thermally conductive tube, which has a longitudinal central axis, which is adapted to be immersed in a thermo-expandable substance of the thermostatic element and in which electric heating means are arranged,
characterized in that one configures a terminal longitudinal portion of the tube so as to flare its free end outward so that said free end extends protruding both radially and axially from the rest of the terminal portion,
then one connects a base made of a plastic substance to the terminal portion, attaching it by overmolding in the flared free end, all while preparing it to support the electric connection between the heating means and an external current source.
The method according to the invention makes it possible to manufacture a heating cartridge as defined above.
According to advantageous features of this method:
The invention will be better understood upon reading the description which follows, provided solely as an example and done in reference to the drawings in which:
In practice, various embodiments can be considered concerning the case 1, the isolating plug 2 and the armature 3, without limiting the invention. Thus, for example, the portion 31 of the armature 3 can be absent, the bearing seat of the isolating plug 2 then being defined directly by the case 1.
To control the movement of the isolating plug 2, the thermostatic valve includes a thermostatic element 4 comprising, in a manner well known in the field, on one hand a cup 41, which contains a thermo-expandable substance, not visible in the figures, and around which the isolating plug 2 is fixedly connected, for example by pushing in, and on the other hand a piston 42, which is partially immersed in the cup 41 and which can be moved in translation along its central longitudinal axis under the action of the expansion of the thermo-expandable substance contained in said cup. The thermostatic element is arranged opposite the case 1 such that, on one hand, its piston 42 is centered on the axis X-X and, on the other hand, this piston is fixedly connected to the body 11, here at the bend of said body 11, as specified in more detail below. Thus, during use, the piston 42 is fixed in relation to the case 1, while the cup 41 and the isolating plug 2 it supports can be moved along the axis X-X in relation to the case, under the effect of the thermo-expandable substance when said substance expands, or indeed, when said substance contracts, under the opposite effect of a return spring 5 inserted between the isolating plug 2 and a U-bolt 32 integral with the case 1, here belonging to the armature 3.
The thermostatic valve also includes a heating cartridge, detailed below and illustrated alone in
The heating cartridge comprises an electric heating resistor 6 which, as visible in
In its upper terminal portion 44, the piston 42 is configured with a free end 45 flared outward: as visible in
The heating cartridge also comprises a base 7 made up of a plastic substance, integral with the terminal portion 44 of the piston 42, with insertion of a gasket 8. More precisely, the base 7 is made up of a body made of plastic substance 71 integrally connected to the terminal piston portion 44 by overmolding thereof, extending axially from a single axial side of said terminal piston portion 44: the base body 71 thus comprises a lower base 72 occupying the internal volume of the terminal piston portion 44, as well as upper walls 73 extending axially protruding upward from the base 72, as shown in
The base 72 coats the inner peripheral portion 82 of the annular body 81 of the joint 8, while the outer peripheral portion 83 of the gasket body 81 protrudes radially outwardly in relation to the base body 71 and here presents peripheral sealing lips 84 on its outer side face. The body 81 of the gasket 8 is provided with a lower groove 85, which is hollowed upward from the lower face of the body 81, radially between its portions 82 and 83. This groove 85 is dimensioned to receive the flange 46 of the flared free end 45 of the piston 42 in a complementary manner, as shown in
To manufacture the heating cartridge from the piston 42 shown in
The manufacture of the heating cartridge is completed by the realization of fittings in order to electrically connect the heating resistor 6 and an external current source. To do this, two electric conduction wires 62 coming from the main heating body 61 are provided to pass all the way through, along the direction of the axis X-X, the base body 71. In practice, before the overmolding of the base 7, the heating body 61 is placed inside the terminal portion 43 of the piston 42 such that the wires 62, which are connected to said heating body 61, or constitute the ends thereof, extend to the outside of the piston 42, passing through the terminal portion 44 from which they emerge upward while presenting respective free ends 63, as illustrated in
The ends 63 of the wires 62 are then folded downward, respectively inside free volumes V7 defined by the base body 71 between its walls 73. These free volumes V7, advantageously arranged during the molding of the base body 71, are dimensioned to receive ports 91, which are partially shown in dotted lines in
In the assembled configuration of the thermostatic valve, the flared free end 45 of the piston 42 is received inside the cavity 13, so as to house the base 7 and the gasket 8 therein, as illustrated in
When the thermostatic valve is in use, the base 7 is pressed against the bottom wall 14 of the cavity 13 under the action of the thermostatic element 4 and the return spring 5: the corresponding axial strains are transmitted, on one hand, from the piston 42 to the base body 71 through the upper face 47A of the bent wall 47, and, on the other hand, from the base body 71 to the bottom wall 14, through the upper face 71A of this base body. The significant radial dimensions of the two aforementioned faces 47A and 71A guarantee a reliable transmission of stress, without damaging the base body 71.
Furthermore, it is understood that the total axial dimension Δof the heating cartridge, between the lower end of the piston 42 and the upper face 71A of the base 7, as indicated in
With an adjustment of the axial dimension of the base 7 during molding thereof, the heating cartridge can be manufactured precisely with different dimensions Δ, while also guaranteeing good mechanical strength of said base, and with a low manufacturing cost.
Various arrangements and variations of the heating cartridge and thermostatic valve described above can also be considered. For example:
Maraux, Thierry, Pottie, Nicolas
Patent | Priority | Assignee | Title |
9844097, | Dec 14 2012 | VERNET | Heating assembly for a thermostatic valve and corresponding production method, and a thermostatic valve comprising such an assembly |
Patent | Priority | Assignee | Title |
8217319, | Mar 11 2009 | VERNET | Heating cartridge and thermostatic element including same |
DE10303133, | |||
FR2853710, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 09 2010 | VERNET | (assignment on the face of the patent) | / | |||
Mar 09 2010 | POTTIE, NICOLAS | VERNET | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 024221 | /0908 | |
Mar 09 2010 | MARAUX, THIERRY | VERNET | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 024221 | /0908 |
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